Failure of ventral closure and axial rotation in embryos lacking the proprotein convertase Furin.

We have examined the role of Furin in postimplantation-stage mouse embryos by analyzing both the expression pattern of fur mRNA and the developmental consequences of a loss-of-function mutation at the fur locus. At early stages (day 7.5), fur mRNA is abundant in extraembryonic endoderm and mesoderm, anterior visceral endoderm, and in precardiac mesoderm. 1 day later fur is expressed throughout the heart tube and in the lateral plate mesoderm, notochordal plate and definitive gut endoderm. Embryos lacking Furin die between days 10.5 and 11.5, presumably due to hemodynamic insufficiency associated with severe ventral closure defects and the failure of the heart tube to fuse and undergo looping morphogenesis. Morphogenesis of the yolk sac vasculature is also abnormal, although blood islands and endothelial precursors form. Analysis of cardiac and endodermal marker genes shows that while both myocardial precursors and definitive endoderm cells are specified, their numbers and migratory properties are compromised. Notably, mutant embryos fail to undergo axial rotation, even though Nodal and eHand, two molecular markers of left-right asymmetry, are appropriately expressed. Overall, the present data identify Furin as an important activator of signals responsible for ventral closure and embryonic turning.

cDNA cloning, genomic organization, and expression of the human RTN2 gene, a member of a gene family encoding reticulons.

This paper describes the cDNA cloning, genomic organization, and expression of the human RTN2 gene on chromosome 19q13.3, which was recognized by virtue of its high similarity with the human RTN1 (formerly called NSP) gene on chromosome 14q21-q22. In a region of about 12 kb in total, 11 RTN2 exons could be identified. Like the RTN1 gene, the RTN2 gene is transcribed into different mRNA variants. Two have a size of about 2.3 kb, and a third has a size of about 1. 3 kb. The two 2.3-kb transcripts differ because of alternative splicing of exon 5. Transcription of the 1.3-kb transcript starts presumably from an internal promoter within exon 5. The three mRNAs encode three different proteins, RTN2-A (545 aa), RTN2-B (472 aa), and RTN2-C (205 aa), which share a common carboxy-terminal segment of 201 aa. In this common segment, the homology with the RTN1 proteins, with yet unknown function, is found. Two hydrophobic subregions are present, which are thought to be responsible for the association of the RTN1 and RTN2 proteins with the endoplasmic reticulum. The amino-terminal regions of the RTN2-A and RTN2-B proteins are rich in negatively charged residues and in proline and serine residues and contain multiple potential phosphorylation sites. Analysis of the expression of the RTN2 gene shows differential expression in human tissues with a strikingly high expression of the 1.3-kb transcript in skeletal muscle.

Neuronal differentiation is accompanied by NSP-C expression.

Neuroendocrine-specific protein (NSP) reticulons are expressed in neural and neuroendocrine tissues and cell cultures derived therefrom, while most other cell types lack NSP-reticulons. Three major subtypes have been identified so far, designated NSP-A, NSP-B, and NSP-C. We have investigated the correlation between the degree of neuronal differentiation, determined by morphological and biochemical criteria, and NSP-reticulon subtype expression. For this purpose, several human neuroblastoma cell lines, exhibiting different degrees of neuronal differentiation, were examined immuno(cyto)chemically. It became obvious that the expression of NSP-C, as detected by immunofluorescence microscopy and Western blotting, is most prominent in cell lines with a high degree of neuronal differentiation, such as LA-N-5. Such highly differentiated cells also express other neural and neuroendocrine markers, such as neural cell adhesion molecule (NCAM), neurofilament proteins, synaptophysin, and chromogranin. NSP-A was observed in all cell lines to a different extent. However, no clear correlation was observed with the degree of neuronal differentiation as defined by other neuronal and neuroendocrine markers or morphology. NSP-B could not be detected. The induction of neuronal differentiation with nerve growth factor, dbcAMP, and retinoic acid in the rat pheochromocytoma cell line PC12 and the human teratocarcinoma cell line hNT2, respectively, induced the expression of NSP-A and NSP-C in these cell lines parallel to the induction of neurofilament protein expression. It is concluded that NSP-C expression, in particular, is strongly correlated with neuronal differentiation.

Biosynthesis, distinct post-translational modifications, and functional characterization of lymphoma proprotein convertase.

Proprotein convertases are responsible for the endoproteolytic processing of prohormones, neuropeptide precursors, and other proproteins within the constitutive and regulated secretory pathways. Cleavage occurs carboxyl-terminally of basic amino acid motifs, such as RX(K/R)R, RXXR, and (R/K)R. As already available for the other known mammalian members of this enzyme family, we here define structural and functional features of human lymphoma proprotein convertase (LPC). Analysis of expression of recombinant LPC in stably transfected Chinese hamster ovary cells reveals biosynthesis of a 92-kDa nonglycosylated precursor (proLPC) and a 102-kDa endoglycosidase H-sensitive glycosylated form of proLPC. Only the latter is further processed and after propeptide removal converted into a complexly N-glycosylated mature form of LPC of about 92 kDa. Co-expression experiments of truncated LPC with an active site mutant of LPC (LPCS265A) indicate that prodomain removal of LPC occurs via an autoproteolytic, intramolecular mechanism, as was demonstrated before for some of the other members of this enzyme family. Prodomain removal is shown to be required for LPC to exit the endoplasmic reticulum. As far as subcellular localization is concerned, immunocytochemical, ultrastructural, and biochemical analyses show that LPC is concentrated in the trans-Golgi network, associated with membranes, and not secreted. Carboxyl-terminal domains are critically involved in this cellular retention, because removal of both the hydrophobic region and the cytoplasmic tail of LPC results in secretion. Of interest are the observations that LPC is not phosphorylated like furin but is palmitoylated in its cytoplasmic tail. Finally, substrate specificity of LPC is similar to that of furin but not identical. Whereas for furin a basic substrate residue at position P-2 is dispensable, it is essential for LPC. For optimal LPC substrate processing activity, an arginine at position P-6 is preferred over an arginine at P-4.

A comparison of NSP-reticulons with conventional neuroendocrine markers in immunophenotyping of lung cancers.

Neuroendocrine-specific protein (NSP)-reticulons are endoplasmic reticulum-associated protein complexes, which have been identified as markers for neuroendocrine differentiation. In this study, the expression of two members of the family of NSP-reticulons, NSP-A and NSP-C, have been investigated in different types of lung cancer and compared with the expression patterns of five conventional neuroendocrine markers, the neural cell adhesion molecule (NCAM), synaptophysin, chromogranin A, Leu-7, and neurofilament proteins. NSP-A and NSP-C antibodies were reactive with most carcinoid tumour and small cell lung carcinoma (SCLC) cases, while atypical carcinoid tumours showed a variable expression. In the total group of neuroendocrine tumours, a high concordance of expression was found between NSP-A and NSP-C, while their expression correlated well with NCAM and synaptophysin positivity. Chromogranin A, Leu-7, and neurofilament proteins were shown to be expressed to a limited extent in these neuroendocrine tumours. In a selected group of non-SCLCs known to exhibit neuroendocrine features, NSP-A expression was detected at much higher frequency than NSP-C. In virtually all NSP-A positive cases, this expression was associated with one or more of the other neuroendocrine markers. NSP-A expression showed a stronger correlation with conventional neuroendocrine markers than NCAM. In detecting neuroendocrine differentiation in non-SCLC, NSP-A is more sensitive than synaptophysin, chromogranin A, Leu-7, and neurofilament proteins. It is concluded that NSP-reticulons are valuable markers in the diagnosis of neuroendocrine differentiation in non-SCLC and should be used in conjunction with NCAM.

Genomic organization of the human NSP gene, prototype of a novel gene family encoding reticulons.

Recently, cDNA cloning and expression of three mRNA variants of the human NSP gene were described. This neuroendocrine-specific gene encodes three NSP protein isoforms with unique amino-terminal parts, but common carboxy-terminal parts. The proteins, with yet unknown function, are associated with the endoplasmic reticulum and therefore are named NSP reticulons. Potentially, these proteins are neuroendocrine markers of a novel category in human lung cancer diagnosis. Here, the genomic organization of this gene was studied by analysis of genomic clones isolated from lambda phage and YAC libraries. The NSP exons were found to be dispersed over a genomic region of about 275 kb. The present elucidation of the genomic organization of the NSP gene explains the generation of NSP mRNA variants encoding NSP protein isoforms. Multiple promoters rather than alternative splicing of internal exons seem to be involved in this diversity. Furthermore, comparison of NSP genomic and cDNA sequences with databank nucleotide sequences resulted in the discovery of other human members of this novel family of reticulons encoding genes.

Neuroendocrine-specific protein C (NSP-C): subcellular localization and differential expression in relation to NSP-A.

A mouse monoclonal antibody RNL-4, as well as rabbit polyclonal antiserum POL-8 were raised against a synthetic peptide, encompassing the first twenty unique amino-terminal amino acid residues of NSP-C. The specificity of both immunoreagents was established in an ELISA assay using the synthetic peptide and by their immunoreactivity to NSP-C fusion proteins. Immunofluorescence analysis of COS-1 cells, transfected with NSP-C cDNA, showed staining of the endoplasmic reticulum with RNL-4 and POL-8. No cross-reactivity of these reagents with NSP-A or NSP-B was seen. Immunohistochemical studies in normal human tissues showed expression of NSP-C in tissues of neural and neuroendocrine origin, i.e. neurons of the central and peripheral nervous system, the neurohypophysis, adrenal medulla, adenohypophysis, pars intermedia, and in sporadic neuroedocrine cells of the lung. Expression of NSP-C was found in several small cell lung cancer (SCLC) cell lines, in non-SCLC cell lines with neuroendocrine features, but not in typical non-SCLC cell lines. Also, in a neuroblastoma cell line NSP-C expression was observed. Immunoblotting and immunoprecipitation studies with RNL-4 and POL-8 identified the 23 kDa NSP-C polypeptide in these cell lines. Immunofluorescence microscopy showed that also in these cell lines NSP-C is located at the endoplasmic reticulum, as shown before for NSP-A and NSP-B. In some of the cell lines coexpression of NSP-A and NSP-C was observed, while in others only one of the two could be detected. The differential expression of NSP-A and NSP-C in these cell lines is confirmed by immunoblotting and was also evident at the mRNA level. When NSP-A and NSP-C were coexpressed, the number of NSP-C-positive cells was always less than the number of NSP-A-positive cells. A partial colocalization of NSPs was observed in the endoplasmic reticulum. Cell fractionation studies revealed that both proteins are retained in the membranous fraction of the cell, from which they can be solubilized by Triton X-100. Immunoprecipitation analyses under native conditions indicate that NSP-C does not need to associate with NSP-A to form high molecular weight NSP-reticulons.

A new member of the proprotein convertase gene family (LPC) is located at a chromosome translocation breakpoint in lymphomas.

A new member of the proprotein convertase gene family (LPC) has been identified at a chromosome translocation breakpoint occurring in a high grade lymphoma. The translocation t(11;14)(q23;q32) has been molecularly cloned and shown to be the result of a fusion between an intron in the 3' -untranslated region of LPC with a sequence close to the switch region S gamma 4 of the IGH locus. The LPC gene encodes a protein of 785 amino acids with substantial homology to furin and the other members of the proprotein convertase family and represents a novel target for chromosome translocation and subsequent deregulation.

Production of recombinant proteins in Chinese hamster ovary cells overexpressing the subtilisin-like proprotein converting enzyme furin.

The proprotein processing enzyme furin is the mammalian prototype of a novel family of subtilisin-like serine endoproteases which possess cleavage specificity for sites involving multiple basic amino acid residues and are involved in the processing of precursor proteins of a variety of regulatory peptides and proteins. One of the limiting steps in the engineering of mammalian cells designed for the overproduction of secreted proteins is the endoproteolytic cleavage of the precursor molecule to its mature biologically active form. The extremely low level of endogenous furin is likely the reason why cells are not able to fully mature overexpressed precursor proteins to their mature form. Here, we report a CHO-derived cell line genetically engineered for the production of high levels of recombinant proteins that need such endoproteolytic maturation. First, the human furin cDNA under the control of the cytomegalovirus early promoter and enhancer was introduced and overexpressed in a DHFR-deficient CHO cell line. A permanent cell line CHO-D3-FUR was established that expressed biologically active furin. Subsequently, to demonstrate the capacity of CHO-D3-FUR cells to produce recombinant proteins in a fully matured form, two derivative cell lines were established that overexpressed the von Willebrand factor (vWF) and transforming growth factor beta 1 (TGF beta 1); CHO-D3-vWF and CHO-D3-TGF beta 1, respectively. Both derivative cell lines were able to produce relatively high levels of recombinant protein in a fully matured and biologically active form. Our results illustrate the potential of the CHO-D3-FUR cell line in the production of recombinant secretory proteins that need endoproteolytic activation at the consensus furin cleavage sequence Arg-X-Lys/Arg-Arg.

Assignment of the human proprotein convertase gene PCSK5 to chromosome 9q21.3.

The human PCSK5 gene, which encodes a subtilisin-like proprotein processing enzyme, has been mapped by analysis of somatic cell hybrids and YAC clones as well as fluorescence in situ hybridization to chromosome 9q21.3 near markers D9S175 and D9S276.

The Dfur2 gene of Drosophila melanogaster: genetic organization, expression during embryogenesis, and pro-protein processing activity of its translational product Dfurin2.

The gene structure and expression of the Dfur2 gene of Drosophila melanogaster, which encodes the subtilisin-like serine endoprotease Dfurin2, was studied. The Dfur2 gene is very compact in contrast to the related Dfur1 gene, which has an estimated size of over 100 kbp. The 6-kb Dfur2 mRNA is encoded by 16 exons dispersed over a genomic region of about 9 kbp. The exon/intron organization shows conservation of intron positions not only in comparison with Dfur1, but also with the related mammalian genes FUR, PC1/PC3, PC2, and PC4. This conservation supports the hypothesis that all genes belonging to the family of subtilisin-like pro-protein processing enzymes are evolutionary related by descent from a common ancestral gene. In primer extension experiments, Dfur2 transcription initiation sites were identified in the presumed Dfur2 promoter region. This region was found to contain general RNA polymerase II promoter elements like a potential TATA box, a potential CAP signal, and several potential CCAAT boxes. Also, several sequence motifs putatively corresponding to binding sites for Drosophila transcription factors like zeste, bicoid, and engrailed were found to be present. RNA in situ hybridization experiments on Drosophila embryos revealed presumably maternal Dfur2 expression until the syncytial blastoderm (stage 5 of embryogenesis), no expression during gastrulation (stage 9), transient expression in a subset of neurons in the central nervous system of stage 12-13 embryos, and, from stage 13 onwards, expression in the developing tracheal tree. In a vaccinia expression system, the endoprotease Dfurin2 not only cleaved wild-type precursor of von Willebrand factor (pro-vWF) with pro-region cleavage site R-S-K-R decreases, but also, although to a lesser extent, pro-vWF mutants in which the P2 (vWFK-2A) or P4 (vWFR-4A) basic residue with respect to the pro-region cleavage site had been mutated. This cleavage specificity resembles that of human furin. The cleavage of pro-vWF by Dfurin2 shows that the previously reported lack of cleavage of the precursor of the beta A-chain of activin-A by Dfurin2 in this vaccinia expression system is substrate determined.

Endoproteolytic cleavage of its propeptide is a prerequisite for efficient transport of furin out of the endoplasmic reticulum.

The trans-Golgi network (TGN) proprotein convertase furin is synthesized in a zymogenic form and is activated by intramolecular, autoproteolytic cleavage of the propeptide from its precursor. To obtain insight in possible functions of the furin propeptide, we have studied biosynthesis, propeptide cleavage, biological activity, and intracellular localization of human and bovine furin. Analysis of autocatalytic cleavage site mutants of furin revealed that efficient propeptide cleavage requires the presence of the complete furin cleavage consensus sequence Arg-X-Lys-Arg. In studies of a mutant in which the P1 + P4 + P5 residues of the autoproteolytic cleavage site were substituted, no substrate processing activity could be demonstrated, indicating a complete block of maturation. In immunofluorescence analysis, this mutant was found in the endoplasmic reticulum (ER), suggesting ER retention of profurin. This ER retention, however, appeared saturable. Furin proteins encoded by oxyanion hole mutant N188A and negative side chain mutant D248L, which possess autoprocessing activity but lack substrate processing activity, were found in the Golgi and the ER, respectively. Finally, analysis of a furin mutant, in which all three potential sites for N-linked glycosylation were altered, revealed autocatalytic cleavage, substrate processing, and transport to the Golgi. Our results indicate that cleavage of the propeptide occurs in the endoplasmic reticulum and is necessary but not sufficient for transport of furin out of this compartment.

Processing specificity and biosynthesis of the Drosophila melanogaster convertases dfurin1, dfurin1-CRR, dfurin1-X, and dfurin2.

Pro-protein and pro-hormone convertases are subtilisin/kexin-like enzymes implicated in the activation of numerous precursors by cleavage at sites mostly composed of pairs of basic amino acids. Six members of this family of enzymes have been identified in mammals and named furin (also called PACE), PC1 (also called PC3), PC2, PACE4, PC4, and PC5 (also called PC6). Multiple transcripts are produced for all the mammalian convertases, but only in the cases of PC4, PACE4, and PC5 does differential splicing result in the modification of the C-terminal sequence of these enzymes. A similar molecular diversity is also observed for the convertases of Hydra vulgaris, Caenorhabditis elegans, and Drosophila melanogaster. In the third species, two genes homologous to human furin called Dfur1 and Dfur2 have been identified. The Dfur1 gene undergoes differential splicing to generate three type I membrane-bound proteins called dfurin1, dfurin1-CRR, and dfurin1-X, which differ only in their C-terminal sequence. By using recombinant vaccinia viruses that express each of the dfurin proteins, we investigated the potential effect of the C-terminal domain on their catalytic specificities. For this purpose, these enzymes were coexpressed with the precursors pro-7B2, pro-opiomelanocortin, and pro-dynorphin in a number of cell lines, and the processed products obtained were characterized. Our studies demonstrate that these proteases display cleavage specificities similar to that of mammalian furin but not to that of PC2. In contrast, we noted significant differences in the biosynthetic fates of these convertases. All dfurins undergo rapid removal of their transmembrane domain within the endoplasmic reticulum, resulting in the release of several truncated soluble forms. However, in the media of cells containing secretory granules, such as GH4C1 and AtT-20, dfurin1-CRR and dfurin2 predominate over dfurin1, whereas dfurin1-X is never detected. While pro-segment removal occurs predominantly in the trans-Golgi network for all the dfurins, in the presence of brefeldin A, only dfurin1-CRR and dfurin2 can undergo partial zymogen cleavage. The conclusions drawn from the results of this study may well be applicable to the mammalian convertases PC4, PACE4, and PC5, which also display C-terminal sequence heterogeneity.

Subcellular localization and supramolecular organization of neuroendocrine-specific protein B (NSP-B) in small cell lung cancer.

We have recently isolated and characterized a novel gene that is expressed in a neuroendocrine-specific fashion and was therefore designated neuroendocrine-specific protein (NSP)-gene. The NSP-gene encodes three transcripts of different size, with unique 5'-sequences and completely overlapping 3'-sequences. The resulting proteins have an apparent molecular mass of 135 kDa as determined for NSP-A and 23 kDa as found for NSP-C. In the present study we focused on the biochemical characterization and subcellular localization of NSP-B, so far only found to be expressed in the neuroendocrine lung cancer cell line NCI-H82, and its relation to NSP-A. Transfection studies with the NSP-B transcript in COS-1 cells, followed by immunoprecipitation, resulted in a set of proteins ranging in molecular mass from 35 to 45 kDa, identical to NSP-Bs detected by immunoblotting in NCI-H82. In this cell line a major NSP-B triplet in the 43 to 45 kDa range and a 35 kDa NSP-B were consistently detected. Only the 45 kDa NSP-B was found to be phosphorylated. The observed pI values of the 43 to 45 kDa triplet ranged from 4.8 to 5.0, while the 35 kDa NSP-B has a more basic pI value of 5.7. Gel filtration studies show that NSP-A and NSP-B form supramolecular aggregates with a molecular mass of over 500 kDa, present to a minor extent in the phosphate buffered saline soluble cell fraction, but mainly occurring in the membranous pellet fraction from which they can be solubilized by Triton X-100.(ABSTRACT TRUNCATED AT 250 WORDS)

NSP-encoded reticulons, neuroendocrine proteins of a novel gene family associated with membranes of the endoplasmic reticulum.

The novel NSP gene was previously shown to encode, among a variety of neuroendocrine cell types, two 3'-overlapping transcripts, a 3.4 kb one for NSP-A (776 amino acids) and a 1.8 kb one for NSP-C (208 amino acids). The deduced proteins, which were predicted to possess distinct amino-terminal regions, appeared to exhibit some architectural resemblance to known neuroendocrine proteins. In this paper the biochemical characterization and subcellular localization of the two proteins is addressed. In vitro translation of NSP-A and -C RNA produced proteins of about 135 and 23 kDa, respectively. Proteins of similar molecular mass were also detected in immunoprecipitation and western blot analyses of neural and endocrine cells using specific anti-NSP-A or -C antisera; some heterogeneity of NSP-A was observed. NSP-A, but not NSP-C, appeared to be highly phosphorylated and preferentially on serine residues. In immunocytochemical studies, we demonstrated that NSP-A and -C are associated with the endoplasmic reticulum; NSP-A was found to co-localize with SERCA2b, a membrane-associated Ca(2+)-ATPase of the endoplasmic reticulum. In Purkinje cells, we found NSP-immunostaining in the perikaryon, the extensive dendritic tree and the axon, also suggesting association with the smooth endoplasmic reticulum. Biochemical studies of NSP-A provided evidence that NSP-A is strongly associated with microsomal membranes and analysis of deletion mutants of NSP-A revealed that the hydrophobic carboxy-terminal portion of the protein, which is also present in NSP-C, is critical for membrane binding. Through database searches, finally, we found two different NSP-related sequences, one in a sequenced region of human chromosome 19, and the second in a human, pancreatic islet-derived partial cDNA, suggesting that the NSP gene is the prototype of a larger gene family. The results of our studies seem to indicate that the NSP-encoded proteins are novel, membrane-anchored components of the endoplasmic reticulum for which we propose the name reticulons.

NSP-encoded reticulons are neuroendocrine markers of a novel category in human lung cancer diagnosis.

The NSP gene was recently shown to constitute the prototype of a novel gene family, to be selectively transcribed in neural and endocrine cells, and to encode three overlapping proteins, NSP-A, NSP-B, and NSP-C. These proteins were collectively designated reticulons, because they were found to be anchored to membranes of the endoplasmic reticulum through their common carboxy-terminal regions. The goal of the present study was to determine whether the reticulons might be used as markers for neuroendocrine differentiation in human lung tumors. Therefore, the tissue distribution of the NSP-A protein was studied and expression in human lung tumors was evaluated. Immunohistochemical analysis of normal tissues with monoclonal antibodies specifically recognizing the NSP-A protein indicated that NSP-A exhibits a distinct neuroendocrine distribution pattern since it was found to be expressed in a variety of cells with an established neuroendocrine phenotype but not in cells lacking such features. Results with specimens of a wide variety of primary human tumors provided further support for this claim. Immunohistochemical analysis of primary lung carcinomas revealed that NSP-A was readily detectable in small cell lung carcinoma (SCLCs) (8 of 12) and carcinoid tumors of the lung (3 of 3) but not in nonneuroendocrine non-SCLCs (0 of 10). In 13 of 27 non-SCLCs expressing the neural cell adhesion molecule and/or neurofilament proteins, however, NSP-A was found to be expressed. Northern blot analysis of human lung carcinoma cell lines revealed expression of NSP-A- and/or NSP-C-encoding mRNAs in all 18 SCLC cell lines that were studied, except one; however, no expression of these mRNAs could be detected in any of the 11 non-SCLC cell lines tested. The NSP transcript encoding NSP-B was found only in SCLC cell line NCI-H82. In conclusion, the results of our studies suggest that, in lung tumor cells, expression of NSP-A and most likely also NSP-C is restricted to cells with a neuroendocrine phenotype.

Molecular analysis of expression in rat brain of NSP-A, a novel neuroendocrine-specific protein of the endoplasmic reticulum.

Previous studies have established that the novel neuroendocrine-specific NSP gene encodes three carboxy-terminally overlapping proteins, NSP-A, NSP-B and NSP-C which are anchored to membranes of the endoplasmic reticulum. Here, we report results of studies in which expression of NSP-A in rat brain was investigated. Immunization of mice with a bacterial hybrid protein containing almost all NSP-A sequences led to the isolation of five monoclonal anti-NSP-A antibodies. The corresponding epitopes were found to be mapping to two regions unique to NSP-A. In Western blot analysis of rat cerebrum and cerebellum using these antibodies, proteins of about 145 kDa were detected. An immunohistochemical study of rat brain revealed the presence of NSP-A in many brain regions, particularly in cerebellar Purkinje cells, in neurons of the superior colliculus and of the pyriform and enthorhinal cortex, in fibers of the basal ganglia and several hippocampal regions including CA3 (stratum lucidum) and the dentate gyrus, in the induseum griseum and in the subcommissural organ, suggesting a role of NSP-A in many areas of the brain.

Expression of the dibasic proprotein processing enzyme furin is directed by multiple promoters.

The prototype mammalian proprotein processing enzyme furin is shown to be encoded by three distinct FUR mRNA isoforms which differ only in their 5'-untranslated regions. By primer extension analysis, the transcription start sites of the three mRNA isoforms were defined. The genomic regions located immediately upstream of the three alternative transcriptional start sites were shown to possess promoter activity in transfection experiments using the luciferase encoding gene as reporter. In a liver cell line, the P1 promoter appeared to be the strongest; in a lung cell line, the P1A promoter. Human FUR promoter P1 but not P1A or P1B was transactivated by transcription factor C/EBP beta. Other members of this family of bZIP transcription factors, C/EBP alpha and C/EBP delta, were not able to transactivate the P1 promoter. Promoter P1A and P1B have characteristics of promoters of housekeeping genes. They lack TATA or CAAT boxes upstream of the transcription start site but are very GC-rich and contain several SP1 sites. Promoter P1, on the other hand, has a TATA box in the proximal promoter region. In electromobility shift assays and DNase I footprinting analysis, transcription factor SP1 was found to bind to the proximal region of the P1 promoter. Altogether, our results indicate that expression of the human FUR gene is directed by alternative promoters, housekeeping (GC-rich) as well as regulated (TATA-containing) promoters, suggesting that their differential use may be a mechanism to modulate levels of the furin enzyme.

Furin-mediated proprotein processing activity: involvement of negatively charged amino acid residues in the substrate binding region.

Furin, which is encoded by the recently discovered FUR gene, appears to be the first known mammalian member of the subtilisin family of serine proteases with cleavage selectivity for paired or multiple basic residues. A consensus cleavage sequence, Arg-X-Lys/Arg-Arg has been proposed. Most likely, furin is primarily involved in the processing of precursors of proteins that are secreted via the constitutive secretory pathway. Homology modelling of the catalytic domain of this protein suggested that negatively charged amino acid residues near or in the substrate binding region might contribute to the observed specificity for substrate segments with paired and multiple basic amino acid residues. To investigate this hypothesis, furin mutants were generated in which negatively charged residues, predicted to be located near or in the substrate binding pockets and involved in interactions with basic residues of the substrate, were replaced by neutral residues. Analysis of processing by these furin mutants of wild-type and cleavage mutants of pro-von Willebrand factor (pro-vWF) revealed that particular negatively charged residues are critical for specific cleavage activity.

Regional mapping of the human NSP gene to chromosome region 14q21-->q22 by fluorescence in situ hybridization analysis.

Genetic sequences of the novel NSP gene, which encodes neuroendocrine-specific proteins, were isolated from cDNA libraries constructed with mRNA isolated from human lung carcinoma cells. Hybridization analysis of a panel of human x mouse cell hybrids with an 0.8-kb NSP cDNA probe indicated that the human NSP gene is probably located on chromosome 14. Fluorescence in situ hybridization analysis of metaphase chromosomes using overlapping genomic clones of NSP as a probe localized the NSP gene to chromosome region 14q21-->q22.